Electrical Spectroscopy of Intervalley Relaxation in WSe2 Transistors

Abstract

We show that the transconductance of multilayer WSe2 field-effect transistors serves as a direct electrical spectrometer of the intervalley relaxation time τ iv, previously accessible only by ultrafast optical techniques. Extending an equilibrium valley-thermodynamics framework with a single relaxation equation for the Γ-valley carrier fraction fΓ(t), we predict three signatures: (i)~a Lorentzian transconductance gm(ω)=gm,0+gm,v0/(1+iωτ iv), whose imaginary part peaks at ωc=τ iv-1 with opposite signs for bilayer and trilayer; (ii)~a two-stage current transient after a gate step, exhibiting bilayer overshoot or trilayer undershoot; and (iii)~sweep-rate-proportional hysteresis whose gate-voltage profile and layer-number sign reversal distinguish valley from trap-induced dynamics. All three signatures provide quantitative electrical access to τ iv with standard rf and dc instrumentation.